DE19837077A1 - Reinforcement cage and its arrangement for the production of reinforced concrete hollow slabs - Google Patents

Abstract

The round steel bent upper ring (20) and the lower ring (18) are fixed to one another coaxially and spaced apart by means of upright braces. The upper ring is reinforced by diagonal horizontal braces. In the reinforcement basket (10) a downwardly open, peripherally closed container (22) can be suspended, the ceiling wall (24) of which has ventilating holes (26). The container in the reinforcement basket is held at least approximately coaxially and the peripheral wall (28) of the container has at least approximately the same horizontal distances from the upright braces of the reinforcement basket. The basket is assembled from a number of U-stirrups (12) which cross one another in the yoke centre. They have teh same angle distances and their legs (14) represent the upright braces.

Description

The invention relates to a reinforcement cage for holding buoyancy-free Hollow bodies for the production of reinforced concrete hollow body slabs and ceilings.

For hollow body ceilings, buoyancy-free hollow bodies have recently been used Unlike previous systems, there is no need to anchor against buoyancy but only to be placed on the formwork or the lower reinforcement layer need. The hollow bodies consist of open cavities, e.g. B. from Expanded rib metal where the air can escape upwards.

The object of the invention is one for such buoyancy-free hollow bodies Reinforcement cage to create the exact arrangement of the hollow body Positions are permitted both in the horizontal plane and in height and one ensures constant concrete coverage of the area and shear reinforcement.

This task is achieved in the reinforcement cage of the type mentioned solved that an upper ring bent from round steel and a corresponding lower Ring are fixed to each other coaxially at a distance by means of standing struts and the upper ring is braced diagonally by means of horizontal struts, and that in the Reinforcement cage, a container that is open at the bottom, is closed at the bottom, whose top wall has ventilation holes, the container in the reinforcement cage is at least approximately coaxial and the peripheral wall of the container of the standing struts of the reinforcement cage at least approximately the same has horizontal distances.

The reinforcement cage is preferably made up of a number of U-brackets composed, which cross each other in the middle of each yoke and the same Have angular distances and the legs of which represent the standing struts.  

A particularly important feature of the invention is that the Reinforcement cage has three U-brackets, the six legs of which in horizontal section Mark the corner points of a hexagon and the two rings are bent and hexagonal are welded at the corners to the legs of the U-bracket.

The reinforcement cages are preferably designed as truncated pyramids, taper so easily from bottom to top, so that they can be stacked one inside the other. The same applies to the cavity-forming containers, which in the simplest case have a circular contour are correspondingly conical. In a preferred embodiment, the Containers also in the form of hexagonal truncated pyramids. The Containers have at least on the peripheral wall, but preferably also on the top wall suspension means to attach them to the reinforcement cage and coaxial to be able to position. The suspension means preferably consist of flexible Tabs that have eyelets so that they can be firmly tied to the fastening basket with wire rope can. These tabs should therefore be flexible so that the containers fit tightly together to be able to stack. The tabs lay against the container walls. Instead of But tabs can also be provided only pairs of holes or individual holes To be able to attach fastening rings or wires to the container.

With the invention it is achieved that the cavity-forming container thanks to the Reinforcement cages can be positioned very precisely. The reinforcement cages serve at the same time as a spacer for the upper reinforcement layers. They are accessible. Shear reinforcement areas can be covered with full reinforcement and concrete realize without changing the cage height very simply that the Reinforcement cages can be used without hanging containers. The one with the reinforcement cages according to the invention and the suspended ceiling achieved has a honeycomb shape that allows minimal wall thicknesses and with regard to the bulge areas is optimally trained.  

The containers are attached to the reinforcement cages both horizontally and in height adapted, the container from the reinforcement cage preferably above and below is towered over. The container peripheral wall preferably runs equidistantly from one of the legs of the U-bracket stretched flat ring. This distance is about 2 cm, which is sufficient for a concrete cover.

In one embodiment, the lower hexagon ring is at the ends of the six Leg attached. This embodiment is suitable for putting on Reinforcement cage on the lower reinforcement layer. Using suitable spacers the reinforcement cages can be positioned exactly and wired to the lower ones Reinforcing layers of reinforcement. An alternative of the invention provides that the Protruding the stirrup legs down over the lower ring. It becomes feet formed, which protrude through the lower reinforcement mats and on the Stand up the panel formwork. In this embodiment there is an advantageous embodiment the invention in that bottom-side fixing plates are used, the three holes for inserting three legs of three adjacent reinforcement cages exhibit. The insertion holes form the corners of an equilateral triangle. This Fixing plates can be made of plastic or wood. Anchoring the Shear reinforcement is ensured by the horizontal ring reinforcement.

It is understood that different for the different ceilings or panel thicknesses Sizes for the reinforcement cages and thus also for the suspended containers are necessary. For example, for a 66 cm concrete slab, there is a reinforcement cage suitable, the lower ring a diagonal of 70 cm and the upper ring one Diagonal of about 60 cm, with a height distance of the two rings of about 46 cm.

Based on the drawing, which illustrates embodiments of the invention, this is described in more detail.

It shows:

Fig. 1 is a three-dimensional view of a new reinforcement cage with hinged container,

Fig. 2 is a side view of the built-in reinforcing cage between a lower and an upper reinforcement layer of a concrete ceiling,

Fig. 3 is a plan view of the reinforcing cage according to FIG. 1 and 2,

Fig. 4, obtained with the reinforcement cages according to Fig. 1 to 3 honeycomb image of a reinforced concrete hollow body ceiling,

Fig. 5 shows a three-dimensional view of a modified embodiment of a reinforcement cage,

Fig. 6 is a side view of the reinforcement cage according to FIG. 5, and

Fig. 7 is a plan view of the reinforcing cage according to FIG. 5 and 6.

A reinforcement cage 10 consists of three U-brackets 12 , which are arranged at an angular distance of 60 ° to one another and whose yokes cross each other in the axis of the reinforcement cage 10 and are welded there. The six legs 14 of the three U-brackets 12 define a truncated pyramid-shaped surface ring with a uniform hexagon cross-section. The U-brackets consist of curved round steel and end in the embodiment according to FIGS. 1 to 3 on the bottom side at a lower hexagon ring 18 , where they are also welded at the corners of this ring. Just below the level of the yokes 16 of the U-bracket 12 , a further hexagon ring 20 is also made of round steel and welded to the legs 14 . The reinforcement cage 10 thus produced is stable and accessible. The circumference of the upper ring 20 is slightly less than that of the lower ring 18 . Accordingly, the legs 14 of the brackets 12 are inclined, thus forming the sides of a trapezoid. In the case of a horizontally positioned reinforcement cage 10 , the legs 14 form an angle of approximately 10 ° with the vertical.

A container 22 is suspended in the reinforcement cage 10 , which is open at the bottom and the top wall 24 of which has a number of ventilation openings 26 . The peripheral wall 28 of the container 22 consists of six flat surfaces which are equidistant from the imaginary surfaces spanned by the bracket legs 14 . The container 22 thus represents a truncated pyramid with a hexagonal. The container periphery is slightly smaller than that defined by the legs 14 Sechseckumfang, wherein the distance between the container walls 28 is dimensioned by the legs 14 for a sufficient concrete cover of the legs 14 and in the embodiment 2 or 3 cm. The container 10 has on the top wall 24 and on the outer edges of the peripheral wall 28 hanging tabs 30 , by means of which the container 22 is fastened to the yokes 16 and the legs 14 of the reinforcement cage 10 , in particular by means of wire.

The reinforcement cages 10 are sufficiently conical to be able to stack them one inside the other. The same applies to the containers 22 , but for which the hanging tabs 30 must be flexible in order to ensure a tight stacking.

The reinforcement cage 10 with the suspended, cavity-forming container 22 is placed on the lower reinforcement layer 32 in a precisely predetermined position and fastened. After the reinforcement cages 10 have completely covered the lower reinforcement layer 32 , the reinforcement cages 10 create a walkable level on which the upper reinforcement 34 is arranged. The reinforcement cages 10 thus carry the upper reinforcement 34 and represent the spacers to the lower reinforcement 32. The yokes of the U-brackets of the reinforcement cages 10 are also fastened to the upper reinforcement 34 .

In the area of high shear stresses, in particular in the support areas, the same reinforcement cages 10 are used , but without the suspended containers 22 .

Fig. 4 shows a plan view of an arrangement of reinforcement cages 10 of a reinforced concrete slab to be produced. As can be seen from this figure, the reinforcement cages 10 are arranged in parallel rows 36 , 38 , one row to the other being offset by half a division. In each case three of the hexagonal contoured reinforcement cages 10 form an imaginary equilateral triangle at three adjacent corners. The suspended containers 22, not shown in FIG. 4, delimit with their wall surfaces the wall webs which result after the concrete has been introduced, as a result of which the concrete ceiling is given a honeycomb structure.

As can be seen from FIG. 2, the container 22 is lower than the reinforcement cage 10 , the top wall 24 of the container 22 being arranged at a distance below the yokes 16 of the reinforcement cage 10 . This provides the upper reinforcement layer 34 with sufficient concrete coverage. The lower edge of the container 22 is also spaced above the lower ring 18 , which rests on the lower reinforcement layer 32 , so that an adequate concrete cover is also ensured here.

The embodiment according to FIGS. 5 to 7 differs from the previously described embodiment only in that the legs 14 of the U-bolts 12 of the reinforcement cage 10 are longer and extend beyond the lower hexagonal ring 18. These leg extensions form feet 40 for the reinforcement cage 10 , which are intended to be placed on the slab formwork. Plastic caps can be used for the foot ends of exposed concrete ceilings. However, the embodiment of FIG. 5 allows, thanks to the projecting feet 40 an elegant positioning system instead of individual caps includes positioning plates having three holes, which form the corners of an equilateral triangle. The three adjacent feet 40 of three adjacent reinforcement cages 10 are then inserted into these holes and can therefore be positioned extremely precisely and therefore also placed closer together in order to create thin honeycomb structures of the cavity ceiling. The length of the feet 40 in the embodiment of FIGS. 5 to 7 is preferably dimensioned such that the lower ring 18 of the reinforcement cage 10 rests on the lower reinforcement layer 32 or from this possibly has a small vertical distance, so that a solid Rödeln of the reinforcement cage 10 at the lower reinforcement 32 is possible.

Claims (16)

1. reinforcement cage for holding buoyancy-free hollow bodies for the production of reinforced concrete hollow body slabs and ceilings, characterized in that an upper ring ( 20 ) bent from round steel and a corresponding lower ring ( 18 ) are fixed coaxially at a distance from one another by means of standing struts and the upper ring ( 20 ) is stiffened diagonally by means of horizontal struts, and that a circumferentially closed container ( 22 ) which is open at the bottom and whose top wall ( 24 ) has ventilation holes ( 26 ) can be suspended in the reinforcement cage ( 10 ), the container ( 22 ) in Reinforcement cage ( 10 ) is held at least approximately coaxially and the peripheral wall ( 28 ) of the container ( 22 ) has at least approximately the same horizontal distances from the standing struts of the reinforcement cage ( 10 ). 2. Reinforcement cage according to claim 1, characterized in that it is composed of a number of U-brackets ( 12 ) which cross each other in the respective yoke center and have the same angular spacing, and whose legs ( 14 ) represent the standing struts. 3. reinforcement cage according to claim 2, characterized in that it has three U-brackets ( 12 ), the six legs ( 14 ) mark the corner points of a hexagon in horizontal section and the two rings ( 18 , 20 ) each bent hexagonally and at the corners are welded to the legs ( 14 ) of the U-bracket ( 12 ). 4. reinforcement cage according to claim 2 or 3, characterized in that the yokes ( 16 ) of the U-bracket ( 12 ) are welded together at their crossing point. 5. Reinforcement cage according to one of claims 1 to 4, characterized in that the yokes ( 16 ) of the U-bracket ( 12 ) run at a distance above the plane spanned by the upper ring ( 20 ). 6. reinforcement cage according to one of claims 1 to 5, characterized in that the lower ring ( 18 ) at the free ends of the legs ( 14 ) of the U-bracket ( 12 ) are welded. 7. reinforcement cage according to one of claims 1 to 5, characterized in that the lower ring ( 18 ) welded at a distance above a by the free ends of the legs ( 14 ) of the U-bracket ( 12 ) defined floor level on the legs ( 14 ) is. 8. reinforcement cage according to one of claims 1 to 7, characterized in that the upper ring ( 20 ) has a smaller circumference than the lower ring ( 18 ) and the legs ( 14 ) to the axis of the reinforcement body ( 10 ) at an angle in the range run at an angle from 3 ° to 20 ° and several reinforcement cages can be stacked one inside the other. 9. reinforcement cage according to one of claims 1 to 8, characterized in that the container peripheral wall ( 28 ) equidistant to a of the legs ( 14 ) of the U-bracket ( 12 ) spanned surface ring. 10. reinforcement cage according to one of claims 1 to 9, characterized in that the top wall ( 24 ) of the container ( 22 ) at a distance below the yokes ( 16 ) of the U-bracket ( 12 ) can be attached. 11. Reinforcement cage according to one of claims 1 to 10, characterized in that the lower edge of the peripheral wall ( 28 ) of the container ( 22 ) lies above the floor plane defined by the free ends of the U-bracket legs ( 14 ). 12. reinforcement cage according to one of claims 1 to 11, characterized in that the container ( 22 ) from the open lower end to the top wall ( 24 ) tapers evenly and is stackable. 13. reinforcement cage according to one of claims 1 to 12, characterized in that the container ( 22 ) on the top wall ( 24 ) and / or on the peripheral wall ( 28 ) suspension means ( 30 ) for coaxially fastening the container ( 22 ) in the reinforcement cage ( 10 ). 14. Arrangement of reinforcement cages ( 10 ) on a lower reinforcement layer ( 32 ) or floor formwork for reinforced concrete slabs or ceilings according to one or more of claims 3 to 13, characterized in that the reinforcement cages ( 10 ) in parallel rows ( 36 , 38 ) are positioned so that the base points of three adjacent legs ( 14 ) of three adjacent reinforcement cages ( 10 ) form an equilateral triangle in horizontal section. 15. The arrangement according to claim 14, characterized in that the side length of the triangle is in the range of one to four times the distance of each leg ( 14 ) from the associated container ( 22 ). 16. The arrangement according to claim 7 and 15, characterized in that the feet ( 40 ) of three adjacent legs ( 14 ) of three reinforcement cages ( 10 ) are inserted into holes in a common positioning plate.